EP3206078A1 - Gleitsichtlinse - Google Patents

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Publication number
EP3206078A1
EP3206078A1 EP15848562.3A EP15848562A EP3206078A1 EP 3206078 A1 EP3206078 A1 EP 3206078A1 EP 15848562 A EP15848562 A EP 15848562A EP 3206078 A1 EP3206078 A1 EP 3206078A1
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EP
European Patent Office
Prior art keywords
lens
power
progressive
refractive power
horizontal direction
Prior art date
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Granted
Application number
EP15848562.3A
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English (en)
French (fr)
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EP3206078A4 (de
EP3206078B1 (de
Inventor
Kazuma Kozu
Takao Tanaka
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Hoya Lens Thailand Ltd
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Hoya Lens Thailand Ltd
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Publication of EP3206078A4 publication Critical patent/EP3206078A4/de
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    • GPHYSICS
    • G02OPTICS
    • G02CSPECTACLES; SUNGLASSES OR GOGGLES INSOFAR AS THEY HAVE THE SAME FEATURES AS SPECTACLES; CONTACT LENSES
    • G02C7/00Optical parts
    • G02C7/02Lenses; Lens systems ; Methods of designing lenses
    • G02C7/06Lenses; Lens systems ; Methods of designing lenses bifocal; multifocal ; progressive
    • G02C7/061Spectacle lenses with progressively varying focal power
    • G02C7/063Shape of the progressive surface
    • GPHYSICS
    • G02OPTICS
    • G02CSPECTACLES; SUNGLASSES OR GOGGLES INSOFAR AS THEY HAVE THE SAME FEATURES AS SPECTACLES; CONTACT LENSES
    • G02C7/00Optical parts
    • G02C7/02Lenses; Lens systems ; Methods of designing lenses
    • G02C7/06Lenses; Lens systems ; Methods of designing lenses bifocal; multifocal ; progressive
    • GPHYSICS
    • G02OPTICS
    • G02CSPECTACLES; SUNGLASSES OR GOGGLES INSOFAR AS THEY HAVE THE SAME FEATURES AS SPECTACLES; CONTACT LENSES
    • G02C7/00Optical parts
    • G02C7/02Lenses; Lens systems ; Methods of designing lenses
    • G02C7/06Lenses; Lens systems ; Methods of designing lenses bifocal; multifocal ; progressive
    • G02C7/061Spectacle lenses with progressively varying focal power
    • G02C7/068Special properties achieved by the combination of the front and back surfaces
    • GPHYSICS
    • G02OPTICS
    • G02CSPECTACLES; SUNGLASSES OR GOGGLES INSOFAR AS THEY HAVE THE SAME FEATURES AS SPECTACLES; CONTACT LENSES
    • G02C2202/00Generic optical aspects applicable to one or more of the subgroups of G02C7/00
    • G02C2202/16Laminated or compound lenses

Definitions

  • the present invention relates to a progressive power lens, in particular relates to a progressive power lens having a both-sides composite progressive structure.
  • a progressive power lens has a part in which a power is progressively changed, and fields of view for viewing different distances (for example, a distance portion for distance vision, a near portion for near vision or the like) can be obtained by a single lens, and therefore the progressive power lens is mainly used as a glasses lens for correction for presbyopia.
  • a progressive power lens having a so-called both-sides composite progressive structure for example, see Patent Literature 1.
  • a power, which is progressively changed is divided into a power change in a vertical direction of the lens (namely, an up and down direction in use of the lens) and a power change in a horizontal direction of the lens (namely, a left and right direction in use of the lens), and sharing rates in respective directions suitable for two surfaces of a front and a rear surfaces are defined, and thereby one progressive power lens is formed.
  • a surface configuration in which the power change in the vertical direction of the lens having a progressive refractive power function is given to only an object side surface (namely, a convex surface), and the power change in the horizontal direction of the lens is given to only an eyeball side surface (namely, a concave surface) is adopted.
  • the front and the rear surfaces of the lens are formed in aspherical surfaces without having a progressive surface, respectively.
  • the progressive power lens having the both-sides composite progressive structure is structurally different from any of “an outer surface progressive power lens” in which a progressive surface is arranged on an object side surface, “an inner surface progressive power lens” in which the progressive surface is arranged on an eyeball side surface, and “a both-sides progressive power lens” in which the progressive surfaces are used for the front and the rear surfaces and a desired addition power is shared by the front and the rear surfaces.
  • both of an advantage of "the outer surface progressive power lens” in which a swing angle of an eyeball when a line of sight is moved between respective fields of view corresponding to different distances can be less, and an advantage of "the inner surface progressive power lens” in which a jumping and warping of images can be reduced by suppressing magnification difference between respective fields of view corresponding to the different distances can be obtained.
  • Patent Literature 1 JP 3617004 B
  • the progressive power lens having the both-sides composite progressive structure since the power change in the vertical direction of the lens and the power change in the horizontal direction of the lens are divided and distributed to the front and the rear surfaces of the lens respectively, when a desired addition power is obtained while keeping the meniscus shape, a surface refractive power (namely, a depth of a lens curve) in the vertical direction of the lens of the object side surface is in a tendency to be larger.
  • a surface refractive power namely, a depth of a lens curve
  • the lens curve of the eyeball side surface becomes thin as a whole, in order to keep the meniscus shape including a near portion, it is necessary to ensure the depth of the lens curve of the object side surface to some extent.
  • the lens curve of the eyeball side surface becomes deeper, and therefore a thickness of the lens for glasses becomes thicker compared to a progressive power lens having a surface configuration in which a progressive surface is arranged on at least one of the front and the rear surfaces of the lens.
  • the progressive power lens having the both-sides composite progressive structure has a unique problem in which outer appearance, performance in fashion or the like as the lens for glasses is deteriorated.
  • an object of the present invention is to provide a progressive power lens having a both-sides composite progressive structure capable of suppressing a surface refractive power (namely, a depth of a lens curve) to be large and capable of achieving thinning of a thickness of the lens.
  • the present invention is devised in order to achieve the object described above.
  • a progressive power lens including:
  • the surface refractive power (namely, the depthof the lens curve) is suppressed to be large and the progressive power lens is suppressed to be thick, and thereby outer appearance, performance in fashion or the like as the lens for glasses can be improved.
  • Figs. 1A and 1B are diagrams for explaining a specific example of a basic configuration of a progressive power lens.
  • the example figures illustrate an example of a configuration of a so-called distance-near type progressive power lens 1.
  • a distance portion 11 formed as a part for a field of view having a power for distance vision is arranged at an upper side in a lens surface
  • a near portion 12 formed as a part for a field of view having a power for near vision is arranged at a lower side in the lens surface.
  • a corridor 13 in which a power is progressively changed is arranged between the distance portion 11 and the near portion 12, and therefore the distance portion 11 and the near portion 12 are smoothly connected by the corridor 13.
  • a progressive power lens 1 As shown in Fig. 1B , all performance which is required in the progressive power lens 1 is given by two surfaces of a surface 2 located at an object side in use of glasses (hereinafter, referred to as merely “obj ect side surface” or “outer surface”) and a surface 3 located at an eyeball side (hereinafter, referred to as merely “eyeball side surface” or “inner surface”) .
  • a surface 2 located at an object side in use of glasses hereinafter, referred to as merely “obj ect side surface” or “outer surface”
  • eyeball side surface eyeball side surface
  • the distance-near type lens is described as an example, as the progressive power lens 1, a so-called intermediate-near type lens, a near-near type lens or the like is known.
  • the progressive power lens 1 in the present description is provided with the corridor 13 in which the power is progressively changed, and therefore the progressive power lens 1 may have at least the near portion 12, which has the power for near vision, arranged in the lens surface.
  • the progressive power lens 1 As the progressive power lens 1 provided with the basic configuration described above, various lenses having various surface configurations are known, and as one of them, a progressive power lens having a both-sides composite progressive structure is known.
  • the power progressively changed is divided into a power change in a vertical direction of the lens and a power change in a horizontal direction of the lens, and sharing rates in respective directions suitable for two surfaces of a front and a rear surfaces are defined, and thereby one progressive power lens 1 is formed.
  • a surface configuration in which the power change in the vertical direction of the lens is given only to the object side surface (outer surface) 2, and the power change in the horizontal direction of the lens is given only to the eyeball side surface (inner surface) 3 is adopted.
  • the outer surface 2 and the inner surface 3 of the lens are formed by aspherical surfaces without having a progressive surface, respectively.
  • the progressive surface denotes a surface in which the distance portion 11 and the near portion 12 are connected in a region called as a corridor in which surface astigmatism is set to be a minimum (approximately 0.25D to 0.50D), and by combining the surface and a spherical surface or a toric surface, a necessary function (correction for presbyopia) for the progressive power lens can be obtained.
  • the progressive power lens having the both-sides composite progressive structure is structurally different from any of “an outer surface progressive power lens” in which a progressive surface is arranged on the outer surface, “an inner surface progressive power lens” in which the progressive surface is arranged on the inner surface, and “a both-sides progressive power lens” in which the progressive surface is given to both of the front and the rear surfaces and a desired addition power is shared by the front and the rear surfaces.
  • Fig. 2 is a diagram illustrating a list for explaining specific examples of a distribution of an addition power in each of the progressive power lenses having the both-sides composite progressive structure and progressive power lenses having other surface configuration.
  • both-sides progressive power lens see a row of "both-sides 1" in figure
  • 50% of the power changes (namely, a required addition power) in both of the vertical direction of the lens and the horizontal direction of the lens are given to the object side surface 2 and the eyeball side surface 3, respectively.
  • 30% of the power changes (namely, a required addition power) in both of the vertical direction of the lens and the horizontal direction of the lens are given to the object side surface 2 and 70% of those are given to the eyeball side surface 3, respectively.
  • the progressive power lens having the both-sides composite progressive structure in one example of the progressive power lens having the both-sides composite progressive structure (see a row of "both-sides composite 1" in figure), 100% of the power change in the vertical direction of the lens (namely, a vertical addition power) is given to the object side surface 2 and 100 % of the power change in the horizontal direction (namely, a horizontal addition power) is given to the eyeball side surface 3.
  • the progressive power lens having the both-sides composite progressive structure see a row of "both-sides composite 2" in figure
  • 100% of the power change in the vertical direction of the lens namely, a vertical addition power
  • 25% of the power change of the horizontal direction of the lens namely, a horizontal addition power
  • the progressive power lens having the both-sides composite progressive structure see a row of "both-sides composite 3" in figure
  • 150% of the power change in the vertical direction of the lens namely, a vertical addition power
  • 150% of the power change in the horizontal direction of the lens namely, a horizontal addition power
  • 100% of the power change in the horizontal direction of the lens is given to the eyeball side surface 3.
  • the power which is changed progressively is divided into the power change in the vertical direction of the lens and the power change in the horizontal direction of the lens, and sharing rates in respective directions suitable for the two faces of the front and the rear surface are defined, and thereby one progressive power lens is formed, and this configuration is different from any of the outer surface progressive power lens, the inner surface progressive power lens, and the both-sides progressive power lens.
  • the progressive power lens having the both-sides composite progressive structure provided with such a surface configuration can include both advantages of the outer surface progressive power lens and the inner surface progressive power lens. Specifically, since a structure in which the power change in the vertical direction of the lens relating to a corridor length is arranged on the outer surface 2 and the power change in the horizontal direction of the lens relating to the jumping and the warping of images is arranged on the inner surface 3 is adopted, both the advantage of the outer surface progressive power lens in which a swing angle of an eyeball when a line of sight is moved between respective fields of view corresponding to different distances can be less and the advantage of the inner surface progressive power lens in which the jumping and the warping of images can be reduced by suppressing magnification difference between respective fields of view corresponding to the different distances can be obtained.
  • the front and the rear surfaces of the lens can be used in a composite manner, and clear field of view can be spread in all of the distance portion, the intermediate portion, and the near portion, and especially, the jumping and the warping of images in a periphery of the lens can be improved.
  • the progressive power lens having the both-sides composite progressive structure as described above is obtained through a schematic procedure of optical design described below.
  • the design procedure of the progressive power lens having the both-sides composite progressive structure includes at least a step of setting information (S1), a step of designing both sides as an outer surface progressive power lens (S2), and a step of converting to a convex shape of a both-sides composite progressive structure and designing a concave shape brought with that (S3).
  • the input information is mainly divided into item specific information as specific data of a lens item, and user specific information as specific data of a lens user.
  • the item specific information includes information relating to a refractive index n of lens material, a progressive surface design parameter represented by a corridor length and the like.
  • the user specific information includes information relating to a distance power (spherical power S, astigmatism power C, astigmatism axis AX, prism power P, prism base direction PAX or the like), an addition power ADD, layout data (distance PD, near PD, eye point position or the like), a frame shape and the like.
  • a surface shape formed as an outer surface progressive power lens is designed in a lens outer surface (a convex surface) and a lens inner surface (a concave surface) based on the received input information.
  • the surface shape of the convex surface namely, the progressive surface
  • the surface shape of the concave surface is designed in accordance with the progressive surface design parameter as the input information.
  • the surface shape of the concave surface for example, a spherical surface or a toric surface as an astigmatism correction surface.
  • the surface shape of the convex surface (namely, the progressive surface) formed as outer surface progressive power lens is converted into a surface shape of a convex surface in the both-sides composite progressive structure in accordance with the distance power, the addition power ADD or the like received as the input information.
  • a progressive power surface is set to fulfill the relational expressions of DHf + DHn ⁇ DVf + DVn and DHn ⁇ DVn, or alternatively, to fulfill the relational expressions of DVn - DVf > ADD/2 and DHn - DHf ⁇ ADD/2.
  • the convex surface is converted to the surface shape of the convex surface in the both-sides composite progressive structure without changing an average surface refractive power in the whole of the convex surface.
  • it is considered to keep a total average value of the surface refractive powers in the vertical direction and the horizontal direction of the distance portion and the near portion.
  • it is preferable to set within a region which keeps the meniscus shape in which the object side surface is formed in a convex shape and the eyeball side surface is formed in a concave shape.
  • a deformation amount in converting is added to a surface shape of the concave surface (namely, the spherical surface or the toric surface as the astigmatism correction surface) formed as an outer surface progressive power lens.
  • the same amount as the deformation amount in converting is added to a side of the lens inner surface (a concave surface).
  • the deformation is like "bending" which bends the lens itself, but it is necessary to pay attention to that it is not uniform deformation over the whole surface, and therefore the surface fulfills the relational expressions described above.
  • the lens for glasses including the progressive power lens keeps the meniscus shape.
  • One reason thereof is considered as below.
  • Fig. 3 is a diagram for explaining one example of a relationship between the lens shape and a direction of line of sight.
  • the Progressive Power Lens having the both-sides composite progressive structure since the power changes in the vertical direction of the lens and the power change in the horizontal direction of the lens are divided and distributed to the front and the rear surfaces of the lens respectively, when the meniscus shape is kept in a whole of the lens, it is considered that the surface refractive power in the object side surface becomes large compared to the progressive power lens in which the progressive surface is arranged on at least one of the front and the rear surfaces of the lens. Especially, in a case in which the lens has a positive power, the surface refractive power is in a tendency to be larger.
  • Figs. 4A to 4C are diagrams for explaining a specific example of the relationship between the surface refractive power of the progressive power lens having the both-sides composite progressive structure and the surface refractive power of the progressive power lens having other surface configuration. Further, in the figures, in a case in which the surface refractive power is changed in the object side surface (the outer surface), a hatching pattern is applied to the section of the lens, and in a case in which the surface refractive power is changed in the eyeball side surface (the inner surface), a dotted pattern is applied to the section of the lens.
  • the surface refractive power of the object side surface (the outer surface) in the near portion becomes larger in both of the vertical direction of the lens and the horizontal direction of the lens. Namely, as the addition power ADD becomes larger, the lens curve of the outer surface in the near portion becomes deeper.
  • the surface refractive power of the eyeball side surface (the inner surface) in the near portion becomes smaller in both of the vertical direction of the lens and the horizontal direction of the lens. Namely, as the addition power ADD becomes larger, the lens curve of the inner surface in the near portion becomes shallower.
  • the surface refractive power of the object side surface (the outer surface) in the near portion becomes larger while the surface refractive power of the eyeball side surface (the inner surface) in the near portion becomes smaller.
  • the lens curve of the outer surface in the near portion becomes deeper while the lens curve of the inner surface in the near portion becomes shallower.
  • the addition power ADD becomes larger
  • the curve in the vertical direction of the lens in the object side surface becomes deeper and the curve in the horizontal direction of the lens in the eyeball side surface becomes shallower, and in such a case, when the meniscus shape is kept, it is necessary to ensure the depth of the curve in the obj ect side surface to some extent.
  • the thickness of the lens for glasses becomes thicker compared to the outer surface progressive power lens, the inner surface progressive power lens and the like.
  • Figs. 5A to 5C are diagrams for explaining a specific example of the surface refractive power in the progressive power lenses.
  • the progressive power lens having the distance power S of +6. 00 diopter (D) and the addition power of ADD + 2.00 D is illustrated as an example.
  • the surface refractive power of the eyeball side surface is to be 0.00 D as much as possible
  • the surface refractive power of the obj ect side surface (the depth of the lens curve) can be a minimum while keeping the meniscus shape. Accordingly, in a case in which S + 6.00 D and ADD + 2.00 D are to be achieved, the surface refractive power of the shallowest object side surface, which is needed to keep the meniscus shape, is +6.00 D.
  • the progressive power lens having the both-sides composite progressive structure of a conventional general configuration in which the power change in the vertical direction of the lens is given only to the object side surface and the power change in the horizontal direction of the lens is given only to the eyeball side surface in a case in which S + 6.00 D and ADD + 2.00 D are to be achieved, as shown in Fig. 5B , it is necessary to set the surface refractive power in the horizontal direction of the lens in the near portion of the obj ect side surface to be + 8. 00 D even if the surface refractive power in the horizontal direction of the lens of the eyeball side surface is set to be 0. 00 D.
  • the surface refractive power in the horizontal direction of the lens is not changed in the object side surface, the surface refractive power in the horizontal direction of the lens in the distance portion becomes +8.00 D.
  • the surface refractive power in the vertical direction of the lens in the distance portion becomes +8.00 D and that in the near portion becomes + 10.00 D.
  • the surface refractive power of the shallowest object side surface which is needed to keep the meniscus shape, is +8.00 D, and it is larger than the outer surface progressive power lens (see Fig. 5C ).
  • the curve of the object side surface in the vertical direction of the lens becomes deeper and the curve of the eyeball side surface in the horizontal direction of the lens becomes shallower.
  • the lens having the positive power as shown in the example in Figs. 5A to 5C since the eyeball side surface becomes shallower as a whole, in order to keep the meniscus shape including the near portion, it is necessary to ensure the depth of the curve of the object side surface to some extent.
  • the lens for glasses is in the tendency to be thicker, and thus the progressive power lens having the both-sides composite progressive structure has a unique problem in which outer appearance, performance in fashion or the like as the lens for glasses is deteriorated.
  • the surface refractive power (namely, the depth of the lens curve) is suppressed to be larger when the both-sides composite progressive structure is adopted to the lens for glasses.
  • the progressive power lens having the both-sides composite progressive structure it is necessary to ensure the depth of the curve of the object side surface to some extent because the lens curve of the eyeball side surface becomes shallower, namely it is because it is desired to obtain the desired addition power while keeping the meniscus shape.
  • the progressive power lens having the both-sides composite progressive structure has a specific surface configuration in which the power change in the vertical direction of the lens and the power change in the horizontal direction of the lens are divided and distributed to the front and the rear surfaces of the lens respectively.
  • the present inventors focused on the specific surface configuration in the progressive power lens having the both-sides composite progressive structure, and the present inventors deemed the surface refractive power in the vertical direction of the lens and the surface refractive power in the horizontal directionof the lens in the eyeball side surface tobe independent and obtained an idea that it may be possible to suppress the lens curve of the object side surface to be deeper by suppressing the lens curve of the eyeball side surface to be shallower.
  • the present inventors deemed the surface refractive power in the vertical direction of the lens and the surface refractive power in the horizontal direction of the lens in the eyeball side surface to be independent and obtained the idea that it may be possible to suppress the surface refractive power of the object side surface to be larger by arranging a shaped part which does not keep the meniscus shape partially on the eyeball side surface.
  • the present invention is completed based on a novel idea by the present inventors in which a shaped part which does not keep the meniscus shape partially is arranged without adhering to a general concept relating to the lens for glasses which keeps the meniscus shape.
  • the progressive power lens having the both-sides composite progressive structure according to one embodiment of the present invention is described. Further here, as the progressive power lens having the both- sides composite progressive structure, a configuration (see Fig. 2 ) in which 100% of the power change in the vertical direction of the lens (namely, the vertical addition power) is given to the object side surface (the outer surface) 2 and 100% of the power change in the horizontal direction of the lens (namely, the horizontal addition power) is given to the eyeball side surface (the inner surface) 3 is described as an example.
  • the progressive power lens having the both-sides composite progressive structure described in the present embodiment has a large characteristic in which "a saddle like part" describe below is arranged in a region part which achieves a function as the near portion of the eyeball side surface (hereinafter, referred to as merely “the near portion of the eyeball side surface”). Further, the position and the region of the near portion in the lens surface are defined by the optical design procedure described above.
  • the saddle like part is a shaped part in which the signs of positive and negative of the surface refractive power in the vertical direction of the lens and the surface refractive power in the horizontal direction of the lens are opposite to each other.
  • the vertical direction of the lens denotes an up and down direction in use of the lens. Further, the up and down direction is not limited to the strict sense of the vertical direction, and the up and down direction includes a direction equivalent to the vertical direction.
  • the horizontal direction of the lens denotes a left and right direction in use of the lens. Further, the left and right direction is not limited to the strict sense of the horizontal direction, and the left and right direction includes a direction equivalent to the horizontal direction.
  • the signs of positive and negative of the surface refractive power denotes a sign of positive and negative adhered to a value of the surface refractive power and denotes a direction of a concave shape and a convex shape of the lens curve.
  • the lens curve protruding in a convex manner toward the object side surface (the outer surface) namely, the lens curve recessed in a recessed manner seen from the eyeball side surface (the inner surface)
  • the surface refractive power is positive is defined as "the surface refractive power is positive”
  • the lens curve protruding in a convex manner toward the eyeball side surface (the inner surface) is defined as "the surface refractive power is negative”.
  • the signs of positive and negative of the surface refractive powers are opposite denotes that the sign of positive and negative relating to the surface refractive power in the vertical direction of the lens and the sign of positive and negative relating to the surface refractive power in the horizontal direction of the lens are different from each other.
  • the surface refractive power in the vertical direction of the lens is positive and the power change in the horizontal direction of the lens is negative.
  • Fig. 6 is a diagram for explaining a three dimensional shape of the lens surface provided with the saddle like part schematically illustrated by a lattice.
  • the example figure illustrates the lens inner surface seen from the eyeball side in a diagonal direction.
  • a plane shape of the lens surface is illustrated as a rectangular shape for an easy understanding, but the actual plane shape of the lens surface is formed in a circular shape before lens fitting processing to a frame is performed.
  • the progressive power lens having the both-sides composite progressive structure described in the present embodiment has a saddle like part 14 in the near portion of the eyeball side surface (the lens inner surface).
  • the eyeball side surface in the progressive power lens has a convex shaped plus curve toward the outer surface in the whole surface region in the vertical direction of the lens and the surface refractive power is made "positive”.
  • the eyeball side surface has a convex shaped plus curve toward the outer surface at a side of the distance portion in the horizontal direction of the lens and the surface refractive power is made "positive”.
  • the saddle like part 14 is arranged at a side of the near port ion, the part corresponding to the saddle like part 14 has a convex shaped minus curve toward the inner surface and the surface refractive power is made "negative".
  • the saddle like part 14 in which the signs of positive and negative of the surface refractive power in the vertical direction of the lens and the surface refractive power in the horizontal direction of the lens are opposite to each other is arranged.
  • the signs of "positive” and “negative” of the surface refractive power in the saddle like part 14 and other part are set as described above, but magnitude of its value is not limited to a specific value.
  • the value of the surface refractive power in each part is determined in the optical design procedure described above based on the received item specific information, the received user specific information or the like.
  • a position or the like in the near portion in which the saddle like part 14 is arranged is not limited to a specific configuration.
  • the position and a region of the saddle like part 14 are, similarly to the position and the region of the near portion, appropriately defined in the optical design procedure described above based on the received item specific information, the received user specific information or the like.
  • the saddle like part 14 is arranged to be apparent in a surface not including a component of prescribed astigmatism.
  • the shaped part as the saddle like part 14 becomes apparent in the lens inner surface.
  • the shaped part in which the signs of positive and negative of the surface refractive powers in the vertical direction of the lens and the surface refractive power in the horizontal direction of the lens are opposite to each other exists apparently as a shape in the lens inner surface.
  • the lens inner surface is formed as the astigmatism correction surface.
  • the correction for astigmatism is performed by a toric surface (or alternatively, a troidal surface) arranged to be inclined to correspond to an astigmatism axis.
  • a component of prescribed astigmatism is added to the shaped part as the saddle like part 14, and the shape of the saddle like part 14 is collapsed, and thereby the saddle like part 14 is buried in the surface shape after the addition of the component of the prescribed astigmatism.
  • the saddle like part 14 may be formed to be apparent after the component of the prescribed astigmatism is removed from the surface. It is because a functional effect described below can be obtained, similarly to the configuration in which the saddle like part 14 is apparent, as long as the shaped part as the saddle like part 14 exists in the lens inner surface even if the shaped part is latent.
  • the saddle like part 14 may be arranged such that its shape is to be apparent in the surface originally not including the component of the prescribed astigmatism or in the surface from which the component of the prescribed astigmatism is virtually removed.
  • the shape as the saddle like part 14 is apparent as an example, but even if the shaped part is latent, as long as the saddle like part 14 becomes apparent after the component of the prescribed astigmatism is removed, a similar function can be achieved.
  • the progressive power lens having the both-sides composite progressive structure has the saddle like part 14 at a partial region in the near portion of the eyeball side surface (the lens inner surface), and the surface refractive power in the horizontal direction of the lens in the regional part in which the saddle like part 14 is arranged is made "negative".
  • the shaped part which keeps the meniscus shape in the whole region of the surface in the vertical direction of the lens while does not keep the meniscus shape in the partial region in the near portion in the horizontal direction of the lens is arranged.
  • the saddle like part 14 is arranged in the partial region in the near portion of the lens inner surface, for example, even if the addition power ADD is set to be large, compared to a case in which the meniscus shape is kept in both of the outer surface and the inner surface, the surface refractive power of the object side surface can be suppressed to be large (namely, the lens curve can be suppressed to be deep).
  • the progressive power lens having the both-sides composite progressive structure according to the present embodiment has the saddle like part 14 in the partial region in the near portion of the lens inner surface, the surface refractive power in the horizontal direction of the lens of the lens inner surface is made partially "negative". Namely, the surface refractive power in the horizontal direction of the lens in the near portion of the lens inner surface becomes for example -2.00 D.
  • the surface refractive power in the horizontal direction of the lens in the near portion of the lens inner surface is -2.00 D
  • the surface refractive power in the horizontal direction of the lens in the near portion of the lens outer surface is +6.00 D.
  • the surface refractive power in the horizontal direction of the lens in the distance portion becomes also +6.00 D.
  • the surface refractive power in the vertical direction of the lens is set to be +6.00 D in the distance portion and +8.00 D in the near portion.
  • the surface refractive power of the lens outer surface can be made small (namely, the lens curve can be made shallow) and the surface refractive power of the lens outer surface can be suppressed to the same extent as the outer surface progressive power lens (see Fig. 5C ).
  • the meniscus shape is kept in the whole region in the surface in the horizontal direction of the lens.
  • the lens curve of the lens outer surface is suppressed to be deep by arranging the saddle like part 14 in the lens inner surface, and at the same time, at least in the vertical direction of the lens (namely, the swing direction of the eyeball when the line of sight is moved between the distance portion and the near portion), an advantage in an optical characteristic by forming the meniscus shape can be obtained.
  • the shaped part which does not keep the meniscus shape partially in the horizontal direction of the lens is arranged by providing the saddle like part 14 in the partial region in the near portion of the lens inner surface, and thereby the lens curve of the lens outer surface is suppressed to be deep.
  • the shaped part which does not keep the meniscus shape partially in the horizontal direction of the lens is arranged, the deterioration (generation of the astigmatism or the like) of the optical characteristic may be occurred compared to, for example, a case in which the meniscus shape is kept in both of the vertical direction of the lens and the horizontal direction of the lens.
  • the eyeball side surface provided with the saddle like part 14 is subjected to aspherical surface correction which corrects the deterioration of the optical characteristic caused by the saddle like part 14.
  • the aspherical surface correction corrects the deterioration of the optical characteristic caused by the saddle like part 14. Accordingly, aspherical surface correction (hereinafter, referred to as “other aspherical surface correction” in order to distinguish from the aspherical surface correction), which corrects deterioration of the optical characteristic not caused by the saddle like part 14, for example the deterioration of the optical characteristic caused by a progressive power function of the front and the rear surfaces of the lens, is not included in “the aspherical surface correction” described here.
  • the present embodiment does not exclude “other aspherical surface correction", and a part from “the aspherical surface correction” or in addition to “the aspherical surface correction", “other aspherical surface correction” may be applied to at least one of the front and the rear surfaces of the lens. Further, “other aspherical surface correction” may be performed by using a well-known technique, and the detailed description thereof is therefore omitted.
  • Examples of the deterioration of the optical characteristic caused by the saddle like part 14 include astigmatism or power error generated by cause in which a line of sight and the lens surface are not perpendicular to each other in use of the lens due to the saddle like part 14, the jumping of images generated in a peripheral vision of the saddle like part 14, or the like.
  • the aspherical surface correction performs the correction to remove or reduce at least one of aspects as the deterioration of the optical characteristic caused by the saddle like part 14 of the astigmatism or the power error generated by cause in which a line of sight and the lens surface are not perpendicular to each other in used of the lens, and the jumping of images generated in a peripheral vision of the saddle like part 14.
  • Such "the aspherical surface correction” maybe performed by a step of correcting a concave surface by transmission design (S4) in addition to each step of S1 to S3 in the optical design procedure described above.
  • the transmission design is a design method to obtain an original optical function in a state in which a user actually uses the lens for glasses, namely it is the design method to add "correction effect" for removing or reducing the generation of the astigmatism, the change in power or the like mainly generated by cause in which a line of sight and the lens surface are not perpendicular to each other.
  • a difference from the original optical performance as a target is gasped by a strict calculation of tracing beam in accordance with a direction of the line of sight, and surface correction (curve correction) which cancels the difference is performed. Further, by repeating this, the difference is made a minimum, and thereby an appropriate solution can be obtained.
  • the eyeball side surface provided with the saddle like part 14 is subjected to "the aspherical surface correction". Accordingly, in a case in which the shaped part which does not keep the meniscus shape partially in the horizontal direction of the lens due to the saddle like part 14 is arranged, the deterioration of the optical characteristic such as the transmission astigmatism, the transmission power error, the generation of the jumping of images in the peripheral vision or the like caused by that can be suppressed.
  • the aspherical surface correction in a case in which the shaped part which does not keep the meniscus shape due to the saddle like part 14 is arranged, namely, in a case in which the shaped part in which the surface refractive power is "negative” and which is formed in a reversed curve seen from other part is arranged, an amount of the reversed curve (magnitude of the surface refractive power being "negative") is reduced and therefore it is possible that the region to be the reversed curve is less.
  • the method called “optimization” is performed and the amount of the reversed curve can be adjusted by the "optimization", and thereby the necessary amount of the reversed curve can be less.
  • the amount of the reversed curve is less from a viewpoint of ensuring a good optical characteristic, but according to the knowledge of the present inventors, the optical characteristic capable of enduring use as the lens for glasses can be ensured even if the amount of the reversed curve is the same as the addition power in the maximum.
  • the aspherical surface correction in here may be applied to at least the eyeball side surface provided with the saddle like part 14. Namely, since “the aspherical surface correction” suppresses the deterioration of the optical characteristic caused by the saddle like part 14, it is considered that “the aspherical surface correction” should be applied to the eyeball side surface provided with the saddle like part 14, but it is not limited to this, and therefore “the aspherical surface correction” may be performed by using both surfaces of the eyeball side surface and the object side surface.
  • the progressive power lens having the both-sides composite progressive structure has the saddle like part 14 in the near portion of the eyeball side surface. Namely, by focusing on the specific surface configuration in the progressive power lens having the both- sides composite progressive structure and deeming the surface refractive power in the vertical direction of the lens and the surface refractive power in the horizontal direction of the lens in the eyeball side surface to be independent, the shaped part (namely, the saddle like part 14) in which the signs of positive and negative of the surface refractive powers in the vertical direction of the lens and the surface refractive power in the horizontal direction of the lens are opposite to each other, is arranged in the near portion of the eyeball side surface.
  • the surface refractive power of the object side surface can be suppressed to be large (namely, the lens curve can be suppressed to be deep) .
  • the progressive power lens having the both-sides composite progressive structure according to the present embodiment is completed based on a novel idea in which the shaped part which does not keep the meniscus shape partially is arranged without adhering to a general concept relating to the lens for glasses which keeps the meniscus shape by arranging the saddle like part 14 in the eyeball side surface according to the novel idea.
  • the progressive power lens having the both-sides composite progressive structure according to the present embodiment, even if the both-sides composite progressive structure is adopted, the surface refractive power can be suppressed to be large, and the thinning of the thickness of the lens can be achieved by suppressing the progressive power lens to be thick, and as a result, the outer appearance, the performance in fashion or the like as the lens for glasses can be improved.
  • the saddle like part 14 is formed as the shaped part in which the signs of positive and negative of the surface refractive power in the vertical direction of the lens and the surface refractive power in the horizontal direction of the lens are opposite to each other, even if such saddle like part 14 is arranged, compared to a case in which the surface refractive powers in both of the vertical direction of the lens and the horizontal direction of the lens are "negative", the degree of the deterioration (generation of the astigmatism or the like) of the optical characteristic can be suppressed.
  • the surface configuration in which the power change in the vertical direction of the lens is given to the object side surface and the power change in the horizontal direction of the lens is given to the eyeball side surface is adopted.
  • the structure in which the power change in the vertical directionof the lens relating to the corridor length is arranged on the outer surface and the power change in the horizontal direction of the lens relating to the jumping and the warping of images is arranged on the inner surface is adopted.
  • both of the advantage of the outer surface progressive power lens in which a swing angle of an eyeball when a line of sight is moved between respective fields of view corresponding to different distances can be less and the advantage of the inner surface progressive power lens in which the jumping and the warping of images can be reduced by suppressing the magnification difference between respective fields of view corresponding to the different distances can be obtained.
  • the front and the rear surfaces of the lens can be used in a composite manner, and clear field of view can be spread in all of the distance portion, the intermediate portion, and the near portion, and especially, the jumping and the warping of images in a periphery of the lens can be improved.
  • the surface refractive power in the vertical direction of the lens is "positive” and the power change in the horizontal direction of the lens is "negative”
  • the degree of the deterioration of the optical characteristic can be suppressed and the surface refractive power of the object side surface can be suppressed to be large (namely, the lens curve can be suppressed to be deep).
  • the aspherical surface correction which corrects the deterioration of the optical characteristic caused by the saddle like part 14 is applied to at least the eyeball side surface provided with the saddle like part 14 such as in the progressive power lens having the both-sides composite progressive structure according to the present embodiment, even if the shaped part which does not keep the meniscus shape partially due to the saddle like part 14 is arranged, the deterioration of the optical characteristic caused by that can be suppressed.
  • the amount of the reversed curve in the shaped part which does not keep the meniscus shape can be reduced by performing the method called "optimization"
  • a thinness of a whole of the lens can be ensured while enhancing the optical characteristic, and the amount to be the reversed curve partially can be reduced and the region to be the reversed curve can be made small.
  • the shaped part formed as the saddle like part 14 becomes apparent in the surface not including the component of the prescribed astigmatism, and this configuration can deal with a prescription for the astigmatism appropriately. Namely, in a case to deal with the prescription for the astigmatism, the shaped part formed as the saddle like part 14 does not lead any bad influence to a surface shape for correcting the astigmatism.
  • the surface refractive power in the object side surface can be firmly suppressed to be large (namely, the lens curve can be suppressed to be deep) due to the shaped part formed as the saddle like part 14.
  • the progressive power lens having the both-sides composite progressive structure the surface configuration in which the power change in the vertical direction of the lens is given to the object side surface and the power change in the horizontal direction of the lens is given to the eyeball side surface is described as an example.
  • the progressive power lens having the both-sides composite progressive structure according to the present invention is not limited to such a surface configuration, and the present invention can be applied to a surface configuration in which the power change in the vertical direction of the lens and the power change in the horizontal direction of the lens are divided and distributed to the object side surface and the eyeball side surface, respectively.
  • the present invention can be similarly applied to a surface configuration, for example, in which the power change in the horizontal direction of the lens is given to the object side surface and the power change in the vertical direction of the lens is given to the eyeball side surface.
  • the saddle like part may be formed such that the surface refractive power in the vertical direction of the lens is to be "negative” and the power change in the horizontal direction of the lens is to be "positive” in the near portion of the eyeball side surface.
  • the surface configuration in which 100% of the power change in the vertical direction of the lens (namely, the vertical addition power) is given to the object side surface and 100% of the power change in the horizontal direction of the lens (namely, the horizontal addition power) is given to the eyeball side surface is described as an example.
  • the progressive power lens having the both-sides composite progressive structure according to the present invention is not limited to such a surface configuration, and the present invention can be applied to a surface configuration in which the power progressively changed is divided into the power change in the vertical direction of the lens and the power change in the horizontal direction of the lens, and sharing rates in respective directions suitable for two surfaces of the front and the rear surfaces are defined, and thereby one progressive power lens is formed.
  • the surface refractive powers in the vertical direction and the horizontal direction of the distance portion and the near portion at a side of the lens outer surface may be set to fulfill the relational expressions of DHf + DHn ⁇ DVf + DVn and DHn ⁇ DVn , or alternatively, to fulfill the relational expressions of DVn - DVf > ADD/2 and DHn - DHf ⁇ ADD/2 .
  • the present invention can be similarly applied to a surface configuration, for example, in which each of the sharing rates of the progressive function in the vertical direction of the lens of the object side surface and the sharing rate of the progressive function in the horizontal direction of thelensof the eyeball side surface is set to at least exceed 50%.
  • an amount of a positive curve and an amount of a reversed curve which form the saddle like part are adjusted in accordance with a proportion of each of the sharing rates.
  • the progressive power lens having the both-sides composite progressive structure according to the present invention may fulfill at least the relational expression of DHn ⁇ DVn.
  • Fig. 7 is a diagram for concretely explaining a design condition in lenses of examples and comparative examples described below.
  • Fig. 8 is a diagram for concretely explaining a lens surface refractive power of the examples and the comparative examples.
  • the meaning of each item in the figure is as below, and the unit of each item is D (Diopter).
  • Comparative Examples 1, 2 to be compared with the examples of the present invention are brief ly described.
  • Comparative Example 1 is a conventional general progressive power lens having a both-sides composite progressive structure.
  • Comparative Example 2 is a progressive power lens having a both-sides composite progressive structure in which the progressive power lens of Comparative Example 1 is subjected to the aspherical surface correction which corrects the deterioration of the optical characteristic (corresponding to "other aspherical surface correction" described above).
  • each of the surface refractive power in the vertical direction and the surface refractive power in the horizontal direction is made a value of "positive".
  • a progressive power lens according to Example 1 has the saddle like part 14 in a partial region in the near portion of the lens inner surface. As apparent from Fig. 8 , the progressive power lens according to Example 1 has the saddle like part 14 and thereby the surface refractive power in the horizontal direction of the lens is made "negative" in the partial region in the near portion of the lens inner surface.
  • the surface refractive power in the near portion of the lens inner surface is set as shown in Fig. 9 and Fig. 10 .
  • Fig. 9 is a diagram for concretely explaining the surface refractive power in the vertical direction of the lens in the lens inner surface nearportion of Example 1.
  • Fig. 10 is a diagram for concretely explaining the surface refractive power in the horizontal direction of the lens in the lens inner surface near portion of Example 1. Further, the example figures illustrate a specific value of the surface refractive power only in the partial region around the near power measurement point N.
  • the surface refractive power is made "positive” and the meniscus shape is kept in the vertical direction of the lens, and a part in which the surface refractive power is made "negative” (in a frame illustrated by a bold line in figure) is arranged in the partial region in the near portion in the horizontal direction of the lens.
  • Fig. 11A is a diagram illustrating a specific example of the surface refractive power of a lens surface of Example 1. Further, in drawing, a specific example of the surface refractive power of a lens surface of Comparative Example is also shown as Fig. 11B .
  • the progressive power lens according to Example 1 has the saddle like part 14 in a partial region in the near portion of the lens inner surface and the surface refractive power in the horizontal direction of the lens in the partial region is made "negative" , when compared to a case in which the meniscus shape is kept in a whole surface region of the lens inner surface as shown in Comparative Example 1, even if the same distance power, the same addition power ADD or the like is set (see Fig. 7 ), magnitude of the surface refractive power (namely, the depth of the lens curve) of the lens outer surface can be made relatively small. This is also apparent from Fig. 8 . Accordingly, the progressive power lens according to Example 1 can achieve the thinning of the thickness of the lens easily compared to Comparative Example 1.
  • the progressive power lens according to Example 2 has the saddle like part 14 in a partial region in the near portion of the lens inner surface, and the aspherical surface correction which corrects the deterioration of the optical characteristic caused by the saddle like part 14 is applied.
  • the progressive power lens according to Example 2 is formed by adding the aspherical surface correction to the progressive power lens of Example 1. Accordingly, also in the progressive power lens according to Example 2, as apparent from Fig. 8 , the surface refractive power in the horizontal direction of the lens is made "negative" in the partial region in the near portion of the lens inner surface.
  • the surface refractive power in the near portion of the lens inner surface is set as shown in Fig. 12 and Fig. 13 .
  • Fig. 12 is a diagram for concretely explaining the surface refractive power in the vertical direction of the lens in the lens inner surface near portion of Example 2
  • Fig. 13 is a diagram for concretely explaining the surface refractive power in the horizontal direction of the lens in the lens inner surface near portion of Example 2.
  • the example figures illustrate a specific value of the surface refractive power only in the partial region around the near power measurement point N.
  • the surface refractive power is made "positive” and the meniscus shape is kept in the vertical direction of the lens, and a part in which the surface refractive power is made “negative” (inside a frame illustrated by a bold line in figure) is arranged in the partial region in the near portion in the horizontal direction of the lens.
  • Figs. 14A to 14D are diagrams illustrating a specific example of distribution of transmission astigmatism of Examples 1, 2, and Comparative Examples 1, 2.
  • Each of illustrations in the figures corresponds to a circular region having a radius of 25 mm on the lens, and a pitch of the coordinate is set to 5 mm. Further, an interval of a contour is set to 0.25 D.
  • the aberration is increased at a peripheral part in the lens surface in the distribution of the transmission astigmatism in Example 1 (see Fig. 14C ).
  • the progressive power lens according to Example 2 is subj ected to the aspherical surface correction in order to cancel such an increment of the aberration. Specifically, in the progressive power lens according to Example 2, the correction for removing or reducing at least one item of the astigmatism and the power error generated by cause in which the line of sight and the lens surface are not perpendicular to each other in use of the lens due to the saddle like part 14 and the jumping of images generated in the peripheral vision of the saddle like part 14 is applied. Further, in the progressive power lens according to Example 2, "other aspherical surface correction" which is not caused by the saddle like part 14 is also applied.
  • the progressive power lens according to Example 2 can obtain substantially the same distribution of the transmission astigmatism as that of Comparative Example 2 (see Fig. 14B ).
  • Fig. 15 is a diagram for explaining the specific examples of the transmission astigmatism on a horizontal section passing a near portion measurement reference point compared among Examples 1, 2, and Comparative Examples 1, 2.
  • the transmission astigmatism on the horizontal section passing the near portion measurement reference point is also substantially the same as that of the comparative example 2.
  • the progressive power lens according to Example 2 can achieve the thinning of the thickness of the lens and further substantially the same optical characteristic as that of Comparative Example 2.
  • the aspherical surface correction is applied to the eyeball side surface provided with the saddle like part 14, the deterioration of the optical characteristic caused by the saddle like part 14 can be suppressed, and the thinning of thickness of the lens as a whole of the progressive power lens having the both-sides composite progressive structure can be achieved, and further, the amount of the reversed curve necessary for the thinning can be reduced and the region to be the reversed curve can be small.
  • Fig. 16 is a diagram for concretely explaining the surface refractive power in the vertical direction of the lens in the lens inner surface near portion according to Example 3
  • Fig. 17 is a diagram for concretely explaining the surface refractive power in the horizontal direction of the lens in the lens inner surface near portion according to Example 3.
  • the example figures illustrate a specific value of the surface refractive power only in the partial region around the near power measurement point N.
  • the surface refractive powers in both of the vertical direction of the lens and the horizontal direction of the lens are made values of "positive".
  • the astigmatism correction function is given to the side of the lens inner surface, and it is dared to adopt an example of the astigmatism axis AX of 90°.
  • the astigmatism axis AX is 90°
  • the component of the prescribed astigmatism in which the surface refractive power in the horizontal direction is "positive” is added to the surface refractive power in the lens inner surface, and thereby the surface refractive power of a whole of the lens inner surface is shifted to a side of "positive”, and as a result, the characteristic of the saddle like part 14 becomes latent.
  • the progressive power lens according to Example 3 a configuration in which the component of the prescribed astigmatism is virtually removed from the lens inner surface is described.
  • the removal of the component of the prescribed astigmatism is performed, for example, by means of a vector subtraction of the surface refractive power necessary for the correction for the prescribed astigmatism from each point of the surface refractive power (see Fig. 17 ) before the removal.
  • the vector subtraction in here may be a well-known technique and therefore, and the detailed description of the method is omitted.
  • Fig. 18 is a diagram for concretely explaining the surface refractive power (after the component of the prescribed astigmatism is removed) in the vertical direction of the lens in the lens inner surface near portion according to Example 3
  • Fig. 19 is a diagram for concretely explaining the surface refractive power (after the component of the prescribed astigmatism is removed) in the horizontal direction of the lens in the lens inner surface near portion according to Example 3.
  • the example figures illustrate a specific value of the surface refractive power only in the partial region around the near power measurement point N.
  • the saddle like part 14 which is apparent in the surface after the component of the prescribed astigmatism is removed (namely, the surface not including the component of the prescribed astigmatism) is arranged, even if the saddle like part 14 is latent in a state in which the component of the prescribed astigmatism is included, similarly to that of Example 1, the thinning of the thickness of the lens can be achieved. More specifically, also in the progressive power lens according to Example 3, similarly to that of Example 1, the saddle like part 14 is arranged in the partial region in the near portion of the lens inner surface (even if the saddle like part 14 is latent) .
  • the progressive power lens according to Example 3 can achieve the thinning of the thickness of the lens easily compared to that of Comparative Example 1.

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  • Physics & Mathematics (AREA)
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  • General Physics & Mathematics (AREA)
  • Optics & Photonics (AREA)
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EP3859434A4 (de) * 2018-09-28 2022-07-27 Hoya Lens Thailand Ltd. Gleitsichtlinse und entwurfsverfahren dafür
EP3859432A4 (de) * 2018-09-28 2022-08-03 Hoya Lens Thailand Ltd. Gleitsichtlinse und entwurfsverfahren dafür

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CN112930495B (zh) * 2018-09-28 2023-09-29 豪雅镜片泰国有限公司 渐进屈光力镜片的设计系统、渐进屈光力镜片的设计方法和渐进屈光力镜片组
JP7466137B2 (ja) * 2019-09-26 2024-04-12 学校法人北里研究所 サーバ装置、発注システム、情報提供方法、およびプログラム
CN112505945A (zh) * 2020-11-23 2021-03-16 魏炳松 一种双面复合减薄变焦近视镜片的制备方法

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AU2003235418B2 (en) 2002-05-28 2007-08-16 Hoya Corporation Double-sided aspheric varifocal power lens
JP3617004B2 (ja) * 2002-05-28 2005-02-02 Hoya株式会社 両面非球面型累進屈折力レンズ
JP3882764B2 (ja) 2003-02-19 2007-02-21 セイコーエプソン株式会社 累進屈折力レンズ
JP4301399B2 (ja) * 2003-09-11 2009-07-22 Hoya株式会社 眼鏡レンズの性能評価方法及び眼鏡レンズの設計方法
EP1906227B1 (de) * 2005-06-24 2016-08-10 Hoya Corporation Verfahren zur herstellung einer gruppe von doppelt progressiven brillenlinsen
JP4973027B2 (ja) 2005-08-22 2012-07-11 セイコーエプソン株式会社 累進屈折力レンズ
JP5042032B2 (ja) * 2005-11-18 2012-10-03 Hoya株式会社 成形品の製造方法、ガラス素材、ならびにガラス素材および成形型の面形状決定方法
EP2130090A4 (de) * 2007-03-07 2011-11-02 Pixeloptics Inc Multifokallinse mit einer region mit fortschreitender optischer stärke und einer diskontinuität
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JP2010097205A (ja) * 2008-09-17 2010-04-30 Tokai Kogaku Kk 累進屈折力レンズの設計方法及び製造方法
JP5952541B2 (ja) * 2011-09-30 2016-07-13 イーエイチエス レンズ フィリピン インク 光学レンズ、光学レンズの設計方法、および光学レンズの製造装置
JP5976366B2 (ja) * 2012-04-05 2016-08-23 イーエイチエス レンズ フィリピン インク 累進屈折力レンズおよび累進屈折力レンズの設計方法

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EP3859434A4 (de) * 2018-09-28 2022-07-27 Hoya Lens Thailand Ltd. Gleitsichtlinse und entwurfsverfahren dafür
EP3859432A4 (de) * 2018-09-28 2022-08-03 Hoya Lens Thailand Ltd. Gleitsichtlinse und entwurfsverfahren dafür

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WO2016056649A1 (ja) 2016-04-14
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EP3206078B1 (de) 2020-05-20
US20170293159A1 (en) 2017-10-12
CN107003544B (zh) 2019-08-13
JP6483147B2 (ja) 2019-03-13
CN107003544A (zh) 2017-08-01

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